NONHISTONE NUCLEAR PROTEINS OF RAT BRAIN

Abstract— The rat brain was dissected into cerebral cortex, cerebellum and the remaining regions. From the nuclei, isolated from these three brain sections, were extracted two fractions of nuclear sap proteins (proteins soluble in 014 M NaCl and proteins soluble in 01 M Tris-HCl buffer pH 7-6) and two fractions of nonhistone chromosomal proteins (one soluble in 0-35 M NaCl and one which is not soluble at this salt concentration). Each of these four fractions of the nonhistone nuclear proteins was further separated by polyacrylamide gel electrophoresis. The electrophoretic patterns of the studied fractions of nuclear proteins are qualitatively identical regardless of the brain section from which the analysed protein fraction was isolated. In addition, there arc no qualitative differences in the electrophoretic patterns of nonhistone chromosomal proteins which are and which are not soluble in 0-35 M NaCl. In contrast to the qualitative similarity of the electrophoretic patterns of proteins from different sections of the brain, the amount of the nonhistone nuclear proteins is characteristic for each studied brain section. The ratio of the total nonhistone nuclear proteins to DNA is highest in the brain cortex and lowest in the cerebellum. The most expressed difference between the nuclei is in the ratio of the nonhistone chromosomal proteins soluble in 0-35 M NaCl to DNA. This ratio is 0-52 in the cortex. 0-38 in the mixture of noncortical and noncerebel-lar regions and only 0-18 in the cerebellum. The amount of the three fractions of nonhistone nuclear proteins in the nuclei of individual brain sections is proportional to the activity of the genome in these nuclei. The only exception are the nonhistone chromosomal proteins which are not soluble in 0-35 M NaCl. These proteins and the histones are present in the same amounts in nuclei isolated from all three studied sections of the brain. The results support a proposal that the nonhistone nuclear proteins are involved in the expression of the genetic activity of the cell, without the majority of the proteins in any of the four fractions being the specific regulatory molecules.     

DNA-binding activity of tightly-bound nonhistone chromosomal proteins in chicken liver chromatin.

We have isolated a nonhistone chromosomal protein fraction from chicken liver chromatin which possesses high affinity and preferential sequence DNA binding. Residually DNA-bound nonhistone chromosomal proteins after 2.0 M NaCl extraction of bulk chromatin are isolated. Bound proteins are released by dissociation of the complexes in 5.0 M urea/3.0 M NaCl. We have investigated the in vitro DNA-binding properties of this class. In contrast to other DNA-binding NHCP whose activities have been studied, direct DNA-binding activity is observed which is not abolished under conditions of high ionic strength (to 3.0 M NaCl). Strong preference in binding fractionated homologous DNA is observed, while binding of heterologous (E. Coli) DNA is negligible. The fractionation of homologous DNA permits the isolation of DNA for which this protein class displays strong binding preference, presumably through a concentration of binding sites. The composite data suggest sequence-specific interaction between this protein class and DNA, which is not abolished by high ionic strength.     

Role of nonhistone chromosomal proteins in determining circular dichroism spectra of chromatin.

Complexing of histone proteins, from WI-38 cells with pure DNA from WI-38 cells, causes a marked decrease in the amplitude of the positive ellipticity band and a red shift in circular dichroism spectra in the 250–300 nm region. Total nonhistone chromosomal proteins from WI-38 cells (without histones) cause an analogous effect, but of significantly reduced magnitude. However, the two effects are not additive, because, when DNA is complexed with both histones and nonhistones, the amplitude of the positive ellipticity band has an intermediate value, between the histone-DNA complex and the nonhistone-DNA complex. Removal of certain nonhistone proteins from chromatin of WI-38 cells, by extraction with 0.25–0.35 m NaCl, causes a decrease in the positive circular dichroism band in the 250–300 nm region. Removal of histones and other nonhistone proteins from chromatin by extraction with 0.75 and 1.5 m NaCl causes a strong increase in positive ellipticity. This suggests the existence of modest but definite effects of nonhistone proteins in determining DNA conformation in native chromatin. Taken as a whole, nonhistone chromosomal proteins have a weaker but analogous effect to that of histones, while the nonhistone proteins extractable with 0.25–0.35 m NaCl have an opposite effect.     

Dissociation and reconstitution of chromatin without appreciable degradation of the proteins.

When chromatin from Novikoff hepatoma ascites cells was dissociated in 3 M NaCl – 7 M urea either at pH 6 or 8, degradation of chromosomal proteins was observed in two-dimensional gel electrophoretic patterns. This degradation was not prevented by 50 mM NaHSO₃ but was prevented by 1 mM PMSF (phenylmethylsulfonyl fluoride). Reconstitution of the chromatin components dissociated in 3 M NaCl – 7 M ure ? 0.05 M sodium acetate (pH 6.0) containing 1 mM PMSF resulted in reassociation of DNA, histones and the major nonhistone proteins (B24, B26, B33, BE, BJ, C1, C6, CG, CH, CM, C14, CP, C18, CR, CS and C25). Two-dimensional gel electrophoresis showed that although the proportion of the nonhistone proteins to histones was lower in reconstituted than in native chromatin, the template activity of the reconstituted chromatin was similar to that of native chromatin.     

The occurrence of extended acidic sequences in nonhistone chromosomal proteins

Nonhistone chromosomal proteins and soluble cytoplasmic proteins from rat liver were treated with a combination of proteases and chemical reagents which split a variety of peptide bonds but do not attack sequences consisting predominantly or exclusively of acidic amino acid residues. Analysis of the resulting digests by gel filtration chromatography and column electrophoresis demonstrated that, relative to cytoplasmic proteins, nonhistone chromosomal proteins are rich in highly charged, acidic peptides up to 12 residues in length, but rarely contain very long peptides consisting exclusively of acidic residues such as are found in the nonhistone chromosomal proteins HMG1 and HMG2.     

The fractionation of non-histone chromosomal proteins from rat kidney and liver and their DNA complexes by using the cation exchangers phosphocellulose and SE-Sephadex]

Results of the gradient chromatography of chromosomal nonhistone proteins of the rat liver and kidney and their complexes with DNA on the phosphocellulose and SE-Sephadex are presented. The profiles of elution of the preparation of the homologous tissues with NaCl linear gradient of 0.1-1.0 M are equal. In the fractions of 0.4-0.5 M NaCl, protein components are discovered only in the samples of kidney.     

Degradation of chromosomal proteins during dissociation and reconstitution of chromatin

Histones and nonhistone chromosomal proteins are degraded when chromatin is exposed to 2 M NaCl-5 M urea (pH 6–8) which has been most often used for disscciation and reconstitution of chromatin. Histones and nonhistone proteins are also degraded in 5 M urea (pH 6–8).     

Organ discrimination through organ-specific nonhistone chromosomal proteins

Prefractionation of chromosomal proteins in 5 m urea with stepwise increase in NaCl molarity has been used to facilitate the examination of nonhistone chromosomal proteins isolated from various rabbit tissues. Electrophoretic analysis on polyacrylamide gels under denaturing conditions of the protein fractions derived from brain, liver, heart, and submandibular salivary gland chromatins displays reproducible compositional differences in nonhistone chromosomal proteins. The enzymatic removal of 48% of protein-bound phosphate with alkaline phosphatase does not significantly alter the electrophoretic mobility of these proteins. With the present technique, it is estimated that chromatin polypeptides (of average M_r 100,000) occurring in greater than 3 × 10⁴ copies per genome can be detected. At this level of sensitivity, a significant fraction of total nonhistone chromosomal proteins manifests organ specificity.     

Selective release of chromosomal proteins during limited DNAase 1 digestion of avian erythrocyte chromatin

Duck erythrocyte chromatin has been treated with DNAase 1 under conditions that are known to digest selectively the structural genes coding for globin mRNAs. This limited digestion releases specific sets of nonhistone chromosomal proteins that are not preferentially released during limited digestion with micrococcal nuclease, which does not selectively attack the globin sequences. Analysis of nucleosome monomer and multimer peaks separated on sucrose gradients after limited digestion with micrococcal nuclease shows that the proteins which are released by DNAase 1 digestion remain associated with the chromatin subunits and can be removed by extraction in 0.5 M NaCl. These proteins are tentatively identified as members of the high mobility group (HMG) proteins (originally described by Goodwin, Sanders and Johns, 1973) in terms of their extractability, electrophoretic characteristics and amino acid composition.     

Enrichment of selected active human gene sequences in the placental deoxyribonucleic acid fraction associated with tightly bound nonhistone chromosomal proteins

A DNA fraction which is highly enriched in active gene sequences and tightly associated with a subset of nonhistone chromosomal proteins has been isolated from human placenta. After extraction with 2 M NaCl, placental chromatin was separated into two distinct components by centrifugation. Of the total DNA, approximately 96% (DNA-S) is protein free, while the remaining 4% (DNA-P) is tightly complexed with nonhistone chromosomal proteins. Reassociation studies revealed that the DNA-P fraction was enriched 22-fold in actively transcribed human placental lactogen gene sequences, while the DNA-S fraction was correspondingly depleted 22-fold in these sequences. Approximately 45% of the sequences present in DNA-P (equivalent to 1.8% of the genome) were not present in the DNA-S fraction. Reassociation of nick-translated DNA-P to DNA from a partial digest of DNase I treated nuclei indicated that 27% of the DNA-P sequences were DNAase I sensitive, suggesting they may represent actively transcribed gene sequences. Analysis of the overall sequence organization of DNA-P showed that relative to unfractionated DNA and DNA-S, DNA-P was enriched in single-copy sequences, slightly enriched in the class of middle repetitive sequences from C0t 0.01 to 100 M.s, devoid of the more highly repetitive sequences (C0t less than or equal to 0.01). The distribution of total active placental genes between DNA-P and DNA-S was measured by hybridization with a complementary DNA probe transcribed from total polysomal poly(A+) messenger RNA. We found that 57% of this cDNA probe reassociated to DNA-P and 58% to DNA-S, while 95% reassociated to DNA-P mixed with DNA-S at the observed ratio of 4 to 96, suggesting that the DNA-P fraction contained a different population of active gene sequences than DNA-S. From these results we estimate that approximately 85% of the transcribed sequences appear to be distinctly distributed and equally proportioned between DNA-P and DNA-S, while approximately 15% of the transcribed sequences are common to both fractions. We suggest that the strong affinity of the tightly bound nonhistone chromosomal proteins for the DNA-P fraction indicates a likely role for these proteins in the regulation of gene expression.     

DNA sequence selection by tightly-bound nonhistone chromosomal proteins.

Extraction of chicken reticulocyte chromatin with 2.0 M NaCl removed 96% of chromosomal protein and yields two DNA components after dialysis and high-speed centrifugation. The bulk of chromosomal DNA (ca. 99%) is rendered free of protein, and is thus soluble in 10 mM Tris-HCl, pH 8.0. The other component (ca. 1%) displays a high protein/DNA ratio, and is insoluble in 10mM Tris-HCl, pH 8.0. These DNAs can be separated on the basis of their solubilities. Analysis of the reassociation kinetics with total chicken DNA of these DNAs reveals marked differences. Whereas total DNA and the soluble component (DNA-S) have rapidly reassociating components, the insoluble component (DNA-P) is devoid of these components, and is therefore composed completely of unique sequence DNA. Cot 1/2 values indicate that DNA-S is substantially depleted of some DNA-P sequences. We conclude that this segregation, as determined by tightly-bound nonhistone chromosomal proteins, selects a subset of total genomic DNA sequences, and suggests sequence-specific interaction between the tightly-bound nonhistones and DNA.     

Changes in nonhistone chromatin proteins from liver of young and adult chickens following D-galactosamine administration

The chromatin proteins soluble in 0.35 M NaCl altered during chicken liver development. Administration of D-galactosamine causes variations in the gel patterns of chromatin proteins from chicken liver. The amount of nonhistone protein with a mol. wt of 150,000 decreased both during liver growth and galactosamine application. The majority of age-specific chromatin proteins were, however, unaffected by galactosamine.     

Acid-soluble, non-histone proteins in rat liver chromatin. Interaction with DNA

Some properties of nonhistone proteins of rat liver chromatin (Mr 40 +/- 1 and 41 +/- 1 KD) are described. These proteins are abundant in monomeric particles formed at the early steps of chromatin fragmentation by Ca2+,Mg2+-DNase. The proteins are not extracted from chromatin by 5% HClO4 and 1 M NaCl, but can be extracted by 0.4 n H2SO4 and 2 M NaCl. Study on proteins binding to DNA demonstrated that in 0.05 M NaCl these proteins are bound both to bovine satellite DNA and to the plasmid pBR 322 DNA.     

A contribution of nonhistone proteins to the conformation of chromatin.

1. Changes in circular dichroism (CD) spectra and thermal melting profiles of guinea pigliver DNA reassociated with histones and/or nonhistone proteins from the cerebral of liver chromatin are described. 2. In the DNA-histone complex, positive ellipiticity in the CD spectrum at 260-300 nm is progressively lod by a red-shift of the crossover point at around 260 nm. DNA in this complex is thermally stabilised to a considerable extent, but not to such a full extent as is shown with DNA in native chromatin. 3. DNA-nonhistone complex in 0.14 M NaCl is, in contrast to DNA-histone complex, not precipitable by centrifugation at 20 000 X g. DNA in this complex shows only a slight reduction in ellipticity at 260-300 nm, and a very weak thermal stabilisation. 4. Characteristics in the CD spectrum of the native chromatin are most satisfactorily reproduced in the DNA-histone-nonhistone complex. These include a large decrease in ellipticity at 260-300 nm, a red-shift of the crossover point at around 260 nm, and a slight negative band at around 305 nm. Also, DNA in this complex is thermally stabilised to the extent comparable with DNA in the native chromatin. 5. Addition of nonhistone proteins to the preformed DNA-histone complex in 3 M urea renders a half of the complex, named DNA-histone(-nonhistone), unprecipitable upon centrifugation at 20 000 X g in 0.14 M NaCl. CD spectrum and thermal melting profile of the precipitable DNA-histone(-nonhistone) complex are similar to those of the DNA-histone-nonhistone complex, while in the unprecipitable DNA-histone(-nonhistone) comples, the ellipticity at 260-300 nm is significantly elevated and the highest melting transition (at 80 degrees C) is lacking. 6. The CD spectrum of native cerebral chromatin closely resembles that of unprecipitable DNA-histone(-nonhistone) complex, while in liver chromatin, the spec.trum is an intermediate between those of the unprecipitable and pn of chromatin by nonhistone proteins. Cerebral nonhistone proteins bind to DNA and to the DNA-histone complex more extensively than liver nonhistone proteins. 7. It is concluded that, although the basic conformation of DNA in native chromatin is determined largely by histones, nonhistone proteins also play an individual role. There is also an indication that nonhistone proteins exert an organ-specific modification of chromatin superstructure.     

A comparative study of the nonhistone proteins of rat liver euchromatin and heterochromatin

Rat liver was fractionated into template-active (euchromatin) and template-inactive (heterochromatin) fractions by controlled shearing and glycerol gradient centrifugation. The histone and nonhistone proteins associated with each fraction were compared. No qualitative differences in histone content were observed, but heterochromatin contained 1.5 times more histone protein than did euchromatin. The nonhistone proteins of each chromatin fraction were fractionated on the basis of salt solubility into loosely bound (those extracted by 0.35 m NaCl), tightly bound (those extracted by 2.0 m NaCl), and residual nonhistone proteins (those not extracted by 2.0 m NaCl). Euchromatin contained 3.7 times more loosely bound nonhistone proteins than did heterochromatin, while the latter contained twice as much residual nonhistone protein. Euchromatin was devoid of tightly bound nonhistone protein, a component of heterochromatin. Electrophoretic analysis of these nonhistone protein fractions revealed marked heterogeneity, with a number of bands unique to either eu- or heterochromatin.     

Effect of the conditions of isolation and incubation of the nuclei on digestion of DNA chromatin by calcium- and magnesium-dependent endonuclease. Change in the spectrum of chromosomal proteins and possible role of DNA-protein interactions]

Digesting of chromosomal DNA of interphase rat liver nuclei by Ca, Mg-dependent endonuclease in situ in the presence of chelating agents results in the appearance of the soluble DNP--up to 30% of the total DNA. In addition, 50% of the chromatin is solubilised after mild ultrasonication. In the absence of the chelating agents the degree of fragmentation is considerably increased. The process is accompanied by a loss of some histone and nonhistone chromosomal proteins; the nonhistone proteins are lost selectively. The preliminary removal of the nuclear membrane and significant part of the proteins by tritone X-100 promotes the chromatin degradation and the appearance of low molecular weight fragments. The DNA-fragments of solubilised chromatin are similar to the DNA-fragments of residual chromatin, but in the presence of the chelating agents the latter does not contain monomeric fragments.     

Properties of the genome in normal and SV-40 transformed WI-38 human diploid fibroblasts. III. Turnover of nonhisone chromosomal proteins and their phosphate groups.

The turnover of nonhistone chromosomal proteins and their phosphate groups was compared in normal and in SV-40 virus transformed WI-38 human diploid fibroblasts. Cells were pulse labelled with tryptophan-³H and ³²P for 30 minutes and the specific activities of tryptophan-³H and ³²P in the various molecular weight classes of nonhistone chromosomal proteins were determined during the first four hours following termination of labelling. While a rapid turnover of high molecular weight nonhistone polypeptides (142, 000 to 200, 000 Daltons) is evident after one hour in SV_40 transformed cells, the specific activities of these nonhistone chromosomal polypeptides are not significantly decreased in normal cells. In contrast, a rapid turnover of low molecular weight (30, 000 to 51, 000 Daltons) nonhistone chromosomal proteins occurs during the first hour in normal WI-38 cells with no corresponding decrease in the specific activities of these proteins in SV-40 transformed cells. There is no apparent net turnover of phosphate groups on nonhistone chromosomal proteins in either normal or SV-40 transformed cells four hours following pulse labelling. Rather, during the first four hours significant fluctuations are observed in the ³²P specific activities of defined molecular weight fractions. Taken together with previous reports of differences in the composition, synthesis and phosphorylation of nonhistone chromosomal proteins in normal and SV-40 transformed human diploid cells the present results further indicate the complex nature of the alterations in these proteins which accompany viral transformation.     

The expression of hetero-organic antigens of kidney origin on the surfaces of cultured rat hepatocytes under the influence of the narrow-band fractions of non-histone chromosomal proteins]

Narrow fractions of nonhistone chromosomal proteins (NHCP) eluted with 0.4-0.5 M NaCl from the phosphocellulose column stimulate expression of hetero-organic antigens of kidney origin on the membrane of intact hepatocytes cultured in suspension. These fractions of NHCP were isolated from the intact rats kidney, from cells of hepatoma 27 and Zajdela hepatoma, and from the carcinogenic liver after a single diethylnirozamine injection. The membrane hetero-organic antigens were identified by means of indirect immunofluorescence using specific immune serum.